JP7143910B2 - Receiving device, receiving method and program - Google Patents

Description

The present invention relates to a receiving device, receiving method and program.

Techniques for exchanging signals between a source device and a sink device according to interface standards such as the HDMI (High-Definition Multimedia Interface) (registered trademark) standard and the DVI (Digital Visual Interface) standard are known. For example, Patent Literature 1 discloses a transmitting device (source device) that transmits a reproduced video signal to a receiving device via an HDMI cable, receives the reproduced video signal from the transmitting device via the HDMI cable, and transmits the received reproduced video signal. A receiving device (sink device) that outputs to a display device and displays an image corresponding to the reproduced video signal is disclosed.

Japanese Unexamined Patent Application Publication No. 2013-81062

The transmitting device described in Patent Document 1 transmits a video muting start instruction to the receiving device when video muting is performed in response to detection of a change in the type of reproduced video signal. The receiving device starts the video muting when receiving the video muting start instruction from the transmitting device. The receiving device cancels the video muting when receiving the instruction to cancel the video muting from the transmitting device. When the transmitting device transmits an instruction to cancel video mute to the receiving device, if the communication state between the transmitting device and the receiving device has deteriorated due to a change in the type of reproduced video signal, the receiving device However, there is a possibility of failing to receive the video mute release instruction transmitted from the transmitting device. In this case, even after the transmission device has transmitted a mute release instruction to the reception device, the video mute is unnecessarily continued without being released, making it impossible to display an image corresponding to the reproduced video signal. This is inconvenient for the user.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a receiving apparatus, a receiving method, and a program capable of appropriately controlling output stoppage.

In order to achieve the above object, the receiving device according to the present invention includes:
a signal receiver that receives a data signal, a clock signal, an output stop signal, and an output stop release signal transmitted from the transmitter;
at least one processor;
with
The at least one processor
directing an output in response to the received data signal;
If the output stop signal is received during output according to the data signal, instructing to stop output according to the data signal;
After receiving the output stop signal, the clock signal is changed from a first state in which the clock signal is stable and the data signal can be received to a second state in which the frequency of the clock signal is more unstable than in the first state. and instructing to cancel the output stop even if the output stop cancel signal is not received when detecting that the state has changed from the second state to the first state, and
After receiving the output stop signal, detecting a change to a third state in which the data signal cannot be received although the frequency of the clock signal is constant , and changing from the third state to the first state. If it is detected that the output has been stopped, continue the output stop;
It is characterized by

ADVANTAGE OF THE INVENTION According to this invention, an output stop can be controlled appropriately.

1 is a diagram showing the overall configuration of a projection system according to an embodiment of the invention; FIG. 1 is a diagram showing the configuration of a projection control apparatus according to an embodiment of the invention; FIG. It is a figure showing composition of a projection device concerning an embodiment of the present invention. It is a figure for demonstrating operation|movement of the projection apparatus which concerns on a comparative example. It is a figure for demonstrating operation|movement of the projection apparatus which concerns on embodiment of this invention. 4 is a flowchart for explaining transmission processing executed by the projection control apparatus according to the embodiment of the present invention; 4 is a flowchart for explaining reception processing executed by the projection device according to the embodiment of the present invention; 6 is a flowchart for explaining mute execution control processing executed by the projection device according to the embodiment of the present invention;

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the drawings, the same or equivalent configurations are denoted by the same reference numerals.

A projection system 1 shown in FIG. 1 outputs a content image, which is an image included in content such as a movie or a television program, by projecting it onto a projection surface 2, and outputs content audio, which is audio included in the content. . The projection plane 2 is a plane on which an image can be projected, such as a projector screen, an inner wall of a room, or an outer wall of a building. A projection system 1 includes a projection control device 3 and a projection device 4 . The projection control device 3 is an example of a transmission device, and the projection device 4 is an example of a reception device. The projection control device 3 is a notebook PC (Personal Computer) and is connected to the projection device 4 via an HDMI cable 5, which is a connection cable conforming to the HDMI standard. The projection control device 3 exchanges signals with the projection device 4 according to the HDMI standard by performing wired communication with the projection device 4 via the HDMI cable 5 . As will be described later, the projection control device 3 that is the source device transmits a data signal representing content to the projection device 4 that is the sink device via the HDMI cable 5 . The projection device 4 is a projector, and outputs content images and content sounds according to data signals received from the projection control device 3 . The projection control device 3 also controls the projection device 4 by transmitting a control signal according to an instruction from the user to the projection device 4 via the HDMI cable 5 .

In this embodiment, the projection control device 3 is described as a notebook PC, but this is only an example, and the projection control device 3 can be any electronic device other than a notebook PC, such as a tablet terminal and a smartphone. It's okay. Furthermore, in the present embodiment, the projection control device 3 and the projection device 4 are described as exchanging signals according to the HDMI standard, but this is only an example, and the projection control device 3 and the projection device 4 are connected Signals may be exchanged according to an interface standard other than the HDMI standard, such as the DVI standard, by performing wired communication via a cable. Furthermore, in this embodiment, the transmission device is the projection control device 3, and the reception device is the projection device 4. However, this is only an example, and the transmission device and the reception device can be arbitrary electronic devices. It's okay.

The configuration of the projection control device 3 will be described below with reference to FIG. As shown in FIG. 2, the projection control apparatus 3 includes a CPU (Central Processing Unit) 300, a storage section 301, an operation section 302, a display section 303, a clock signal generation circuit 304, an HDMI transmission section 305, A wireless communication unit 306 and a system bus 307 are provided.

The CPU 300 controls each section of the projection control apparatus 3 according to the programs and data stored in the storage section 301 . The storage unit 301 includes a ROM (Read Only Memory) and a data writable nonvolatile memory such as a flash memory and an EPROM (Erasable Programmable Read Only Memory), both of which are not shown. non-volatile storage of programs and data used for Specifically, the storage unit 301 stores in advance content data representing content including content images and content audio, and frequency determination data described later. The content data is obtained by associating the content image data representing the content image at each time in the period from the content start time to the content end time with the content audio data representing the content audio at each time in the period. Included in sequential order. The storage unit 301 includes a RAM (Random Access Memory) functioning as a work area for the CPU 300 in addition to the ROM and nonvolatile memory described above.

The operation unit 302 includes operators such as a keyboard, touch pad, mouse, and operation switches (none of which are shown), and receives input of various instructions according to user's operations on the operators. The display unit 303 has a display, and displays various images on the display under the control of the CPU 300 . A clock signal generation circuit 304 generates a clock signal having one of a plurality of frequencies under the control of the CPU 300 . The HDMI transmission unit 305 transmits a signal to the projection device 4 according to the HDMI standard under the control of the CPU 300 . Specifically, the HDMI transmission unit 305 includes a connector (not shown) to which the HDMI cable 5 is connected, and performs wired communication with the projection device 4 via the HDMI cable 5, thereby performing a transmission method conforming to the HDMI standard. A signal is transmitted to the projection device 4 by the TMDS (Transition Minimized Differential Signaling) (registered trademark) method. The wireless communication unit 306 performs wireless communication with an external device of the projection control apparatus 3 under the control of the CPU 300 to exchange data with the external device. A system bus 307 is a transmission path for commands and data, and interconnects the CPU 300 to the wireless communication unit 306 .

The CPU 300 functions as the instruction reception unit 30, the signal generation unit 31, and the transmission control unit 32 shown in FIG. In this embodiment, the CPU 300, which is a single processor, functions as the instruction receiving unit 30 to the transmission control unit 32. However, this is only an example, and a plurality of processors are stored in the storage unit 301. It may be configured to cooperate with each other and function as the instruction receiving unit 30 to the transmission control unit 32 by executing the respective programs.

The instruction receiving unit 30 receives various instructions input by the user by operating the operators included in the operation unit 302 . The signal generator 31 generates various signals such as an output start signal, an output end signal, a data signal, a clock signal, a mute instruction signal, and a mute release signal, all of which will be described later. The transmission control unit 32 controls the HDMI transmission unit 305 to transmit the signal generated by the signal generation unit 31 to the projection device 4 via the HDMI cable 5 . Details of the function of each unit will be described below.

When the instruction receiving unit 30 receives an output start instruction to start outputting an image and sound by the projection device 4 in accordance with the user's operation on the operation unit 302, the signal generation unit 31 generates an output start signal and controls transmission. The unit 32 causes the HDMI transmission unit 305 to transmit the output start signal generated by the signal generation unit 31 to the projection device 4 . The output start signal is a control signal that instructs the projection device 4 to start outputting an image and sound. In response to the transmission of the output start signal to the projection device 4, the projection device 4 starts outputting images and sounds. When the instruction receiving unit 30 receives an output end instruction to end the output of the image and sound by the projection device 4 in accordance with the user's operation on the operation unit 302, the signal generation unit 31 generates an output end signal to control transmission. The unit 32 causes the HDMI transmission unit 305 to transmit the output end signal generated by the signal generation unit 31 to the projection device 4 . The output end signal is a control signal that instructs the projection device 4 to end the output of the image and sound. In response to the transmission of the output end signal to the projection device 4, the output of the image and sound by the projection device 4 ends.

The signal generation section 31 generates a data signal representing content according to the content data stored in the storage section 301 . The transmission control unit 32 causes the HDMI transmission unit 305 to transmit the data signal generated by the signal generation unit 31 to the projection device 4 . As will be described later, the projection device 4 outputs images and sounds according to data signals received from the projection control device 3 . In this embodiment, the signal generator 31 generates a data signal according to content data pre-stored in the storage 301, but this is merely an example. The signal generation unit 31 may receive content data from an information processing device external to the projection control device 3 via the wireless communication unit 306 and generate a data signal in real time according to the received content data.

The signal generator 31 generates a content image signal representing a content image and a content audio signal representing content audio as data signals. In other words, the signal generator 31 generates a data signal including a content image signal and a content audio signal. The signal generator 31 generates a content audio signal according to content audio data representing content audio included in content data. Further, the signal generator 31 generates a content image signal according to content image data representing a content image included in the content data. Specifically, the signal generation unit 31 generates, as a content image signal, an image signal representing a content image at the resolution currently set as the output resolution out of the first resolution and the second resolution higher than the first resolution. . Further, the signal generation unit 31 generates an image signal of the signal type currently set as the output signal type among the RGB signal and the YCbCr signal as the content image signal. In addition, the signal generator 31 generates an image signal having a frame rate currently set as the output frame rate out of the first frame rate and the second frame rate higher than the first frame rate, as the content image signal.

The signal generation unit 31 causes the clock signal generation circuit 304 capable of generating clock signals of a plurality of frequencies to generate clock signals of frequencies corresponding to the currently set output resolution, output signal type, and output frame rate. Specifically, the signal generation unit 31 refers to frequency determination data indicating the correspondence between the output resolution, the output signal type, the output frame rate, and the frequency of the clock signal, stored in the storage unit 301. By doing so, the frequency corresponding to the currently set output resolution, output signal type, and output frame rate is specified, and the clock signal generation circuit 304 is made to generate a clock signal of the specified frequency. The transmission control unit 32 causes the HDMI transmission unit 305 to transmit the clock signal generated by the clock signal generation circuit 304 to the projection device 4 . The projection device 4 determines execution timings of various processes according to the clock signal received from the projection control device 3, and executes various processes. The frequency determination data sets the correspondence between the output resolution, the output signal type, the output frame rate, and the frequency of the clock signal by an information processing device external to the projection control device 3, such as a PC or a tablet terminal. After being generated by receiving an operation to do so, it is captured from the information processing apparatus via the wireless communication unit 306 and stored in the storage unit 301 in advance.

When the instruction receiving unit 30 receives any one of an instruction to change the output resolution, an instruction to change the output signal type, and an instruction to change the output frame rate according to the user's operation on the operation unit 302, The signal generator 31 starts setting change processing. In the setting change process, the signal generation unit 31 converts the currently set output resolution, output signal type, and output frame rate to the output resolution, output signal type specified by the user, according to the instruction received by the instruction receiving unit 30. and change to the output frame rate. Furthermore, in the setting change process, the signal generation unit 31 refers to the frequency determination data stored in the storage unit 301 to determine the frequency of the clock signal corresponding to the changed output resolution, output signal type, and output frame rate. The frequency of the clock signal generated by the clock signal generation circuit 304 is changed from the currently set frequency to the specified frequency.

When the projection control device 3 performs setting change processing to change the frequency of the clock signal transmitted to the projection device 4, the frequency of the clock signal is disturbed and the data signal transmitted to the projection device 4 becomes unstable. If the projection device 4 outputs an image and sound in response to an unstable data signal received from the projection control device 3, image flickering or audio noise may occur, which may make the user feel uncomfortable. Therefore, when the instruction reception unit 30 receives an instruction to change the output resolution, output signal type, or output frame rate, the signal generation unit 31 generates a mute instruction signal before starting the setting change process, The transmission control unit 32 causes the HDMI transmission unit 305 to transmit the mute instruction signal generated by the signal generation unit 31 to the projection device 4 . The mute instruction signal is a control signal that instructs the projection device 4 to start a mute process that controls not to output the image and the sound according to the data signal received from the projection control device 3 . In response to the transmission of the mute instruction signal to the projection device 4 , the mute processing by the projection device 4 is started. According to such a configuration, the projection control apparatus 3 transmits a mute instruction signal to the projection apparatus 4 before the setting start process is started, and starts the mute process, thereby allowing the projection control apparatus 3 to respond to the unstable data signal. Images and audio are output to reduce the likelihood of image flickering or audio noise that may annoy the user. That is, according to such a configuration, it is possible to appropriately control the muting process. Mute processing is an example of stopping output in response to a data signal. A mute instruction signal is an example of an output stop signal.

The frequency of the clock signal, which is disturbed by the change in the frequency of the clock signal after the setting change process, becomes constant after the time passes after the setting change process is completed. When the frequency of the clock signal becomes constant, the unstable data signal becomes stable, and even if the projection device 4 outputs an image and sound according to the received data signal, image flickering or sound noise will occur. there is no risk of it happening. Therefore, when the setting change process is completed, it is desirable to end the muting process started with the execution of the setting change process and cause the projection device 4 to resume outputting the image and sound according to the data signal. Therefore, when the setting change processing is completed, the signal generation unit 31 generates a mute release signal, which is a control signal for instructing the projection device 4 to end the mute processing, and the transmission control unit 32 causes the HDMI transmission unit 305 to The mute release signal generated by the signal generation unit 31 is transmitted to the projection device 4 . In response to the transmission of the mute release signal to the projection device 4, the mute processing by the projection device 4 ends. Ending the mute process is an example of canceling the output stop. The mute release signal is an example of the output stop release signal.

In this embodiment, it is assumed that the projection control apparatus 3 changes the frequency of the clock signal when it receives an instruction to change the output resolution, output signal type, or output frame rate, but this is only an example. do not have. The projection control device 3 can change the frequency of the clock signal with the occurrence of any event as a trigger. For example, if the projection device 4 includes a plurality of speakers and is configured to output sound according to the data signal in the currently set sound field mode among the plurality of sound field modes, the user's instruction will be followed. The projection control device 3 may be configured to change the frequency of the clock signal when the sound field mode is changed.

Note that when the instruction receiving unit 30 receives an instruction to start the mute processing of the projection device 4 input by the user by operating the operation unit 302, the signal generation unit 31 generates a mute instruction signal, and the transmission control unit 32 may be configured to cause the HDMI transmission unit 305 to transmit the generated mute instruction signal to the projection device 4 . Further, when the instruction receiving unit 30 receives an instruction for the projection apparatus 4 to end the mute processing input by the user by operating the operation unit 302, the signal generation unit 31 generates a mute release signal, and the transmission control unit 32 may be configured to cause the HDMI transmission unit 305 to transmit the generated mute release signal to the projection device 4 .

The configuration of the projection device 4 will be described below with reference to FIG. As shown in FIG. 3, the projection device 4 includes a CPU 400, a storage unit 401, an operation unit 402, an HDMI reception unit 403, a clock signal stability determination circuit 404, a wireless communication unit 405, and an image projection unit 406. , an audio output unit 407 and a system bus 408 .

The CPU 400 controls each section of the projection device 4 according to the programs and data stored in the storage section 401 . The storage unit 401 includes a ROM and a non-volatile memory, both of which are not shown, and non-volatilely stores programs and data used by the CPU 400 to execute various processes. The storage unit 401 has a RAM functioning as a work area for the CPU 400 . The operation unit 402 includes operators such as operation switches, and receives input of various instructions in accordance with user's operations on the operators. Under the control of the CPU 400, the HDMI receiving unit 403 receives various signals such as the output start signal, the output end signal, the data signal, the clock signal, the mute instruction signal, and the mute release signal from the projection control apparatus 3 according to the HDMI standard. do. HDMI receiver 403 is an example of a signal receiver. Specifically, the HDMI receiving unit 403 has a connector (not shown) to which the HDMI cable 5 is connected, and performs wired communication with the projection control apparatus 3 via the HDMI cable 5 to transmit signals to the projection control apparatus 3 . is received by the TMDS method.

The clock signal stability determination circuit 404 determines whether or not the frequency of the clock signal received by the HDMI receiving unit 403 from the projection control apparatus 3 is constant, that is, whether or not the frequency of the clock signal is stable. A determination signal indicating the result of is output to the CPU 400 . The wireless communication unit 405 performs wireless communication with an external device of the projection device 4 under the control of the CPU 400 to exchange data with the external device. The image projection unit 406 includes a lamp unit, a projection device, and an optical lens unit, all of which are not shown, and projects an image onto the projection surface 2 under the control of the CPU 400 . The audio output unit 407 includes a DAC (Digital-to-Analog Converter), an amplifier, and a speaker, all of which are not shown, and outputs audio under the control of the CPU 400 . A system bus 408 is a transmission path for commands and data, and interconnects the CPU 400 to the audio output unit 407 .

The CPU 400 executes a program stored in the storage unit 401 to control each unit of the projection device 4, thereby performing the reception control unit 40, the output unit 41, the mute processing unit 42, and the reception state determination unit 43 shown in FIG. Function. CPU 400 is an example of a processor. In this embodiment, the CPU 400, which is a single processor, functions as the reception control unit 40 to the reception state determination unit 43. However, this is only an example, and a plurality of processors may be stored in the storage unit 401. By executing the stored programs, they may cooperate with each other to function as the reception control section 40 to the reception state determination section 43 .

The reception control unit 40 controls the HDMI reception unit 403 to transmit various signals such as the output start signal, the output end signal, the data signal, the clock signal, the mute instruction signal, and the mute release signal from the projection control device 3 to the HDMI cable 5. be received via

The output unit 41 causes the image projecting unit 406 to project an image corresponding to the data signal received by the HDMI receiving unit 403 onto the projection surface 2, and causes the audio output unit 407 to project a sound corresponding to the received data signal. output. Specifically, the output unit 41 causes the image projection unit 406 to project the content image represented by the content image signal included in the received data signal, and causes the audio output unit 407 to project the content represented by the content audio signal included in the data signal. output sound. That is, the output unit 41 instructs output according to the data signal received by the HDMI receiving unit 403 . In this embodiment, the output unit 41 outputs both an image and a sound according to the data signal, but this is only an example, and the output unit 41 outputs , it may be configured to output only one of the image and the sound.

The muting processing unit 42 executes muting processing for controlling so that the output unit 41 does not output an image and an audio according to the data signal. Specifically, in the mute processing, the mute processing unit 42 controls the image projection unit 406 to stop outputting the content image corresponding to the content image signal included in the data signal, controls the audio output unit 407, and controls the data signal. The output of the content audio corresponding to the content audio signal included in the signal is stopped. The details of the control of the mute processing by the mute processing unit 42 will be described later. In the mute processing, the mute processing unit 42 stops the output of the image and the sound according to the data signal, and controls the image projection unit 406 to display a blue background, a black screen, or the like, which is different from the content image. The set mute image may be projected onto the projection plane 2 . In this embodiment, the muting process is described assuming that the muting process unit 42 controls the output unit 41 so that both the image output and the audio output in accordance with the data signal are not executed. is just an example. In the muting process, the muting processing unit 42 controls so that one of the image output and the audio output according to the data signal by the output unit 41 is not executed, and also controls the image output according to the data signal by the output unit 41. You may control so that the other is performed among an output and an output of an audio|voice.

The reception state determination unit 43 determines whether the reception state of the clock signal by the HDMI reception unit 403 is a stable signal state in which the HDMI reception unit 403 can receive the data signal from the projection control apparatus 3, and It is determined which of the signal unstable state in which data signals cannot be received from the control device 3 and the state in which the signal is unstable. A signal stable state is an example of a first state. A signal unstable state is an example of a second state. Hereinafter, for ease of understanding, the reception state of the clock signal by the HDMI receiving unit 403 may be simply referred to as "reception state". The stable signal state is the normal reception state, that is, the reception state when communication between the projection control device 3 and the projection device 4 is normally performed. When the reception state is the signal stable state, the HDMI reception unit 403 can normally receive various signals such as data signals from the projection control apparatus 3 . When the frequency of the clock signal transmitted from the projection control device 3 to the projection device 4 is changed by the projection control device 3 performing the setting change processing described above and the frequency of the clock signal is disturbed, the reception state becomes a signal non-signal. become stable. When the receiving state is the signal unstable state, the HDMI receiving unit 403 cannot normally receive various signals such as data signals from the projection control apparatus 3 .

When the receiving state is a stable signal state, the frequency of the clock signal received by the HDMI receiving unit 403 from the projection control apparatus 3 is constant. is in disarray. Therefore, the reception state determination unit 43 controls the clock signal stability determination circuit 404 to determine whether or not the frequency of the clock signal received by the HDMI reception unit 403 is constant. The reception state is determined according to the result of the determination indicated by the received determination signal. Specifically, when the clock signal stability determination circuit 404 determines that the frequency of the clock signal is constant, the reception state determination unit 43 determines that the clock signal stability determination circuit 404 determines that the frequency of the clock signal is stable. If so, it is determined that the reception state is a stable signal state. When the clock signal stability determination circuit 404 determines that the frequency of the clock signal is disturbed, that is, when the clock signal stability determination circuit 404 determines that the frequency of the clock signal is unstable, the reception state determination unit 43 It is determined that the reception state is an unstable signal state. The reception state determination unit 43 determines that the reception state has changed from a stable signal state to an unstable signal state when the frequency of the clock signal that the HDMI receiver 403 continues to receive at a constant frequency is disturbed. When the HDMI receiving unit 403 can continue to receive the clock signal at a constant frequency after the reception state becomes the unstable signal state, the reception state determination unit 43 changes the reception state from the unstable signal state to the signal. It is determined that a stable state has been reached.

Details of control of the mute processing by the mute processing unit 42 will be described below. When the output unit 41 causes the image projection unit 406 and the audio output unit 407 to output an image and audio corresponding to the data signal received by the HDMI reception unit 403, the mute processing unit 42 mutes the HDMI reception unit 403. When a mute instruction signal is received from the projection control device 3, mute processing, which is an example of stopping output, is started. In other words, when the HDMI receiving unit 403 receives the mute instruction signal during output according to the data signal, the mute processing unit 42 instructs to stop output according to the data signal. Note that if the receiving state is not a stable signal state, the HDMI receiving unit 403 cannot receive the mute instruction signal. is a stable signal state. When the HDMI receiving unit 403 receives the mute cancellation signal, the mute processing unit 42 ends the mute processing, which is an example of stopping the output. In other words, the mute processing unit 42 instructs to release the output stop when receiving the mute release signal.

After the timing at which the HDMI receiving unit 403 receives the mute instruction signal, the mute processing unit 42 changes the reception state to a signal based on the disturbance in the frequency of the clock signal that the HDMI receiving unit 403 has been receiving at a constant frequency. When the reception state determination unit 43 determines that the signal has changed from the stable state to the unstable signal state, the reception state changes to the signal unstable state based on the fact that the HDMI receiving unit 403 can continue to receive the clock signal at a constant frequency. When the receiving state discriminating unit 43 discriminates that the signal has changed from the stable state to the stable signal state, even if the HDMI receiving unit 403 does not receive the mute release signal, the mute processing, which is an example of stopping the output, is terminated. In other words, in the mute processing unit 42, after the HDMI receiving unit 403 receives the mute instruction signal, the reception state determination unit 43 detects that the reception state has changed from the stable signal state to the unstable signal state, and When the reception state determination unit 43 detects that the signal has changed from an unstable signal state to a stable signal state, the HDMI receiving unit 403 instructs to release the output stop even if the mute release signal is not received.

That is, when the reception state changes from the stable signal state to the unstable signal state after the timing when the HDMI receiving unit 403 receives the mute instruction signal, the mute processing unit 42 determines whether the HDMI receiving unit 403 has received the mute release signal. The muting process ends at the earlier of the timing and the timing when the reception state changes from the unstable signal state to the stable signal state.

As described above, the mute processing unit 42 controls mute processing according to whether or not the HDMI reception unit 403 has received the mute release signal and the reception state of the HDMI reception unit 403 . With such a configuration, the projection device 4 can appropriately control the muting process.

Specifically, as described above, when executing the setting change process, the projection control apparatus 3 transmits a mute instruction signal to the projection apparatus 4 before starting the setting change process. When the HDMI receiving unit 403 receives the mute instruction signal, the projection device 4 starts mute processing. The projection control device 3 transmits a mute release signal to the projection device 4 when the setting change processing is completed. When the HDMI receiving unit 403 receives the mute release signal, the projection device 4 ends the mute processing. With such a configuration, the projection device 4 reduces the possibility that the muting process ends when the setting change processing has not yet been completed and the projection control device 3 has not transmitted the mute release signal. be able to. According to such a configuration, the projection device 4 has not yet completed the setting change processing, and the data received by the HDMI receiving unit 403 when the receiving state of the HDMI receiving unit 403 is still in an unstable signal state. It is possible to reduce the possibility of image flickering or audio noise occurring by outputting an image and sound in response to a signal. That is, according to such a configuration, the projection device 4 can appropriately control the muting process.

At the timing at which the mute release signal is transmitted from the projection control device 3 to the projection device 4 in response to the completion of the setting change processing, the frequency of the clock signal transmitted to the projection device 4 indicates that the setting change processing has been completed. If the reception state of the HDMI reception unit 403 is still unstable, the HDMI reception unit 403 may fail to receive the mute release signal. At this time, if the projection device 4 controls the termination of the mute processing only based on whether or not the HDMI reception unit 403 has received the mute release signal, the termination of the mute processing is started along with the execution of the setting change processing. The muting process, which should be terminated upon completion, is unnecessarily continued even after the setting change process is completed and the mute cancellation signal is transmitted from the projection control apparatus 3, resulting in the output of images and sounds according to the data signal. is not resumed, which is inconvenient for the user.

However, as described above, when it is determined that the reception state has changed from the stable signal state to the unstable signal state after the timing when the HDMI receiving unit 403 receives the mute instruction signal, the projection apparatus 4 changes the reception state from the signal stable state to the signal unstable state. When it is determined that the signal has changed from the unstable state to the stable state, the mute processing is terminated even if the HDMI receiving unit 403 has not received the mute release signal. With such a configuration, the projection device 4 performs the setting change processing after the timing when the HDMI receiving unit 403 receives the mute instruction signal, and the reception state is stabilized in response to the disturbance of the frequency of the clock signal. When it is determined that the state has changed to an unstable signal state, even if the HDMI receiving unit 403 fails to receive the mute release signal during the period in which the reception state is the unstable signal state, the setting change process is completed and the HDMI When the receiver 403 can continue to receive the clock signal at a constant frequency, the muting process can be terminated in response to the determination that the reception state has changed from the unstable signal state to the stable signal state. . In other words, when the projection device 4 determines that the reception state has changed from a stable signal state to an unstable signal state after the timing at which the HDMI receiving unit 403 receives the mute instruction signal, the mute process being executed is The HDMI receiving unit 403 estimates that the muting process is performed in conjunction with the execution of the setting change process, and estimates that the setting change process is completed when the reception state changes from the unstable signal state to the stable signal state. Terminates ongoing mute processing even if has not received an unmute signal. With such a configuration, the projection device 4 can reduce the possibility that the muting process will continue unnecessarily. That is, the projection device 4 can appropriately control the muting process with such a configuration.

Next, the operation of the projection device 4 will be described by comparing it with the operation of the projection device according to the comparative example. First, FIG. 4 shows the operation of the projection apparatus according to the comparative example, in which the mute processing is started when the mute instruction signal is received from the projection control device 3, and the mute processing is terminated when the mute cancellation signal is received from the projection control device 3. will be described with reference to As described above, the projection device 4 according to the present embodiment controls termination of the muting process according to the reception state of the HDMI reception unit 403, whereas the projection device according to the comparative example controls the reception state of the HDMI reception unit 403. To control the end of mute processing only according to whether or not a mute release signal has been received without considering the reception state.

A case where the projection control apparatus 3 receives an instruction to change the output resolution, the output signal type, or the output frame rate at time T1 shown in FIG. 4 will be described below as an example. It is assumed that the projection control apparatus 3 transmits a mute instruction signal to the projection apparatus 4 at time T2 after time T1 in response to receiving the above instruction at time T1. The projection apparatus according to the comparative example starts muting processing in response to receiving a muting instruction signal from the projection control apparatus 3 at time T2. At time T3 after time T2 when the mute instruction signal is transmitted, the projection control apparatus 3 changes the output resolution, output signal type, or output frame rate, and changes the frequency of the clock signal according to the instruction received at time T1. It is assumed that the setting change processing to be performed is started. It is assumed that the setting change process started at time T3 is completed at time T5. At this time, the reception state of the signal by the projection apparatus according to the comparative example was changed from time T3 when the setting change process was started due to the setting change process for changing the frequency of the clock signal, and the frequency of the clock signal was disturbed. It is assumed that the signal is in an unstable state over a period from time T4 later to time T7 after time T5 at which the setting change process is completed. That is, at time T4, the frequency of the clock signal, which had been constant, is disturbed, and the reception state changes from the signal stable state to the signal unstable state. At time T7, the disturbed clock signal frequency becomes constant, and the reception state changes to the Assume that the unstable state has changed to a stable signal state. In response to the completion of the setting change process at time T5, the projection control device 3 sends a mute cancellation signal to the projection device 4 at time T6 before time T7 when the reception state changes from the unstable signal state to the stable signal state. assumed to have been sent. Assume that the projection apparatus according to the comparative example fails to receive the unmute signal transmitted from the projection control apparatus 3 at time T6 when the reception state is still unstable. In this case, the projection apparatus according to the comparative example should have received the mute release signal from the projection control apparatus 3 at time T6, and should have ended the mute processing according to the received mute release signal. However, due to failure to receive the mute release signal, the mute processing continues without ending even after time T6. In such a case, the output of the image and sound corresponding to the data signal is not resumed after time T6, which is inconvenient for the user.

Next, the operation of the projection device 4 according to the present embodiment will be described with reference to FIG. 5, using as an example the situation similar to the above-described situation used for explaining the operation of the projection device according to the comparative example. That is, in the example shown in FIG. 5, the projection control device 3 receives an instruction to change the output resolution, output signal type, or output frame rate at time T1, and transmits a mute instruction signal to the projection device 4 at time T2. , setting change processing is performed from time T3 to time T5, and a mute cancellation signal is transmitted to the projection device 4 at time T6. At time T<b>2 , the projection device 4 starts mute processing in response to the HDMI reception unit 403 receiving the mute instruction signal from the projection control device 3 . At time T3, the setting change process is started by the projection control apparatus 3. At time T4 after time T3, the frequency of the clock signal, which had been constant, is disturbed, and the reception state of the HDMI receiving unit 403 included in the projection apparatus 4 is changed. , it is assumed that the signal has changed from a stable state to an unstable signal state. At time T5, the setting change processing by the projection control apparatus 3 is completed, and at time T7 after time T5, the frequency of the disturbed clock signal becomes constant, and the reception state changes from an unstable signal state to a stable signal state. state. It is assumed that the projection device 4 fails to receive the unmute signal transmitted from the projection control device 3 at time T6 when the reception state is still unstable. In this case, similarly to the projection device according to the comparative example, the projection device 4 normally receives a mute release signal from the projection control device 3 at time T6, and ends the mute processing according to the received mute release signal. Despite the fact that the mute release signal should have been received, the mute processing continues without ending even after time T6.

However, in the example shown in FIG. 5, the reception state changes from the stable signal state to the unstable signal state at time T4 after time T2 when HDMI receiving section 403 receives the mute instruction signal, and after time T4 Since the reception state has changed from the unstable signal state to the stable signal state at time T7, the projection device 4 ends the mute processing even if the HDMI reception unit 403 has not received the mute release signal. Specifically, it is assumed that the projection device 4 ends the muting process at time T8 after time T7 in response to the reception state changing from the unstable signal state to the stable signal state at time T7. As described above, the projector 4 changes the setting change process from the mute process being executed based on the disturbance of the frequency of the clock signal at the time T4 after the time T2 when the HDMI receiving unit 403 receives the mute instruction signal. When the reception state changes from an unstable signal state to a stable signal state at time T7, it is estimated that the setting change processing is completed, and the muting processing ends at time T8. With such a configuration, the projection device 4 can appropriately control the muting process.

Transmission processing executed by the projection control apparatus 3 having the physical and functional configuration described above will be described below with reference to the flowchart of FIG. A projection control device 3 is connected to a projection device 4 via an HDMI cable 5 . The projection control device 3 acquires content data and frequency determination data generated by an information processing device external to the projection control device 3 via the wireless communication unit 306 and stores them in the storage unit 301 in advance. The display unit 303 displays an instruction reception screen. In this state, when the instruction receiving unit 30 receives an output start instruction for starting the output of the image and sound by the projection device 4, which is input by the user by operating the operation unit 302, the CPU 300 performs the steps shown in the flowchart of FIG. start the transmission process shown.

When the transmission processing shown in the flowchart of FIG. 6 is started, first, the CPU 300 executes transmission start processing (step S101). In the transmission start process, the CPU 300 clears a source mute flag (to be described later) provided in a storage area of the RAM of the storage unit 301 and sets it to an off state, which is an initial state. Furthermore, in the transmission start process, the CPU 300 sets the output resolution to the first resolution, which is the default output resolution, sets the output signal type to the RGB signal, which is the default output signal type, and sets the output frame rate to Set to the first frame rate, which is the default output frame rate. After executing the process of step S101, the signal generation unit 31 generates an output start signal for instructing the projection device 4 to start outputting an image and sound (step S102). After executing the process of step S102, the transmission control unit 32 causes the HDMI transmission unit 305 to transmit the output start signal generated in step S102 to the projection device 4 (step S103).

After executing the process of step S103, the signal generator 31 starts generating data signals and clock signals (step S104). After that, according to the content data stored in the storage unit 301, the signal generation unit 31 sequentially generates data signals representing the details of the content at each time in the period from the start time to the end time of the content in chronological order. The signal generator 31 generates a content image signal and a content audio signal as data signals. The signal generation unit 31 generates an image signal of the currently set output signal type, which expresses the content image with the currently set output resolution according to the content image data included in the content data, and has the currently set output frame rate. is generated as a content image signal. The signal generator 31 generates a content audio signal according to the content audio data included in the content data. In step S104, the signal generation unit 31 refers to the frequency determination data stored in the storage unit 301 to determine the frequency of the clock signal corresponding to the currently set output resolution, output signal type, and output frame rate. and causes the clock signal generation circuit 304 to start generating a clock signal of the specified frequency. After executing the process of step S104, the transmission control unit 32 causes the HDMI transmission unit 305 to start transmitting the data signal and the clock signal (step S105). After that, the HDMI transmission unit 305 sequentially transmits the data signal and the clock signal generated by the signal generation unit 31 to the projection device 4 under the control of the transmission control unit 32 .

After executing the process of step S105, CPU 300 determines whether or not the source mute flag is on (step S106). The source muting flag is set to ON when the projection device 4 is executing the muting process, and is set to be OFF when the projection device 4 is not executing the muting process. In step S106, the CPU 300 determines whether the projection device 4 is executing the mute process by determining whether the source mute flag is on. If it is determined in step S106 that the source muting flag is not set to the ON state, that is, if it is determined that the projection device 4 is not executing the muting process (step S106; No), the instruction receiving unit 30 determines whether or not it has received an instruction to change the currently set output resolution, output signal type, or output frame rate (step S107). If it is determined in step S107 that the instruction receiving unit 30 has not received an instruction to change the output resolution, output signal type, or output frame rate (step S107; No), the process proceeds to step S116.

If it is determined in step S107 that the instruction receiving unit 30 has received an instruction to change the output resolution, output signal type, or output frame rate (step S107; Yes), the signal generating unit 31 generates a mute instruction signal ( step S108). After executing the process of step S108, the transmission control unit 32 causes the HDMI transmission unit 305 to transmit the mute instruction signal generated in step S108 to the projection device 4 (step S109). After executing the process of step S109, CPU 300 sets the source mute flag to the ON state (step S110). Thus, when the instruction receiving unit 30 receives an instruction to change the output resolution, output signal type, or output frame rate (step S107; Yes), the projection control apparatus 3 starts the setting change process (step S111). Before that, a mute instruction signal is transmitted to the projection device 4 (step S109) to cause the projection device 4 to start mute processing. The source mute flag is set to ON when a mute instruction signal is transmitted to the projection device 4 (step S109) and the projection device 4 starts mute processing (step S110).

After executing the process of step S110, the signal generator 31 starts the setting change process (step S111). In the setting change process, the signal generator 31 changes the currently set output resolution, output signal type, and output frame rate to the output resolution, output signal type, and output frame rate specified by the user. Further, in the setting change process, the signal generation unit 31 refers to the frequency determination data to specify the frequency of the clock signal corresponding to the changed output resolution, output signal type, and output frame rate. Change the frequency of the clock signal generated by 304 from the currently set frequency to the specified frequency. After executing the process of step S111, the process proceeds to step S116.

If it is determined in step S106 that the source muting flag is on, that is, if it is determined that the projection device 4 is executing the muting process (step S106; Yes), the CPU 300 starts processing in step S111. It is determined whether or not the setting change processing performed has been completed (step S112). If it is determined in step S112 that the setting change process has not yet been completed (step S112; No), the process proceeds to step S116. When it is determined in step S112 that the setting change process has been completed (step S112; Yes), the signal generator 31 generates a mute release signal (step S113). After executing the process of step S113, the transmission control unit 32 causes the HDMI transmission unit 305 to transmit the mute release signal generated in step S113 to the projection device 4 (step S114). After executing the processing of step S114, CPU 300 clears the source mute flag and sets it to the OFF state (step S115). After executing the process of step S115, the process proceeds to step S116. In this way, when the setting change processing is completed (step S112; Yes), the projection control device 3 transmits a mute release signal to the projection device 4 (step S114) and causes the projection device 4 to end the mute processing. Also, the source mute flag is set to OFF when a mute release signal is transmitted to the projection device 4 (step S114) and the projection device 4 ends the mute processing (step S115).

In step S116, the CPU 300 determines whether or not the instruction receiving unit 30 has received an output termination instruction to terminate the output of the image and sound by the projection device 4 (step S116). If it is determined in step S116 that the instruction receiving unit 30 has not received an output end instruction (step S116; No), the process returns to step S106. If it is determined in step S116 that the instruction receiving unit 30 has received an output termination instruction (step S116; Yes), the transmission control unit 32 causes the HDMI transmission unit 305 to terminate generation of the data signal and the clock signal (step S116; Yes). S117). After executing the process of step S117, the signal generator 31 ends the transmission of the data signal and the clock signal (step S118). After executing the process of step S118, the signal generation unit 31 generates an output end signal for instructing the end of the output of the image and sound by the projection device 4 (step S119). After executing the processing of step S119, the transmission control unit 32 causes the HDMI transmission unit 305 to transmit the output end signal generated in step S119 to the projection device 4 (step S120), and the transmission processing ends.

Next, reception processing executed by the projection device 4 having the physical and functional configuration described above will be described with reference to the flowchart of FIG. A projection device 4 is connected to the projection control device 3 via an HDMI cable 5 . In this state, the projection control device 3 executes the transmission process described above to transmit the output start signal to the projection device 4, and when the HDMI receiving unit 403 included in the projection device 4 receives the output start signal, the CPU 400 The receiving process shown in the flowchart of FIG. 7 is started.

When the reception process shown in the flowchart of FIG. 7 is started, first, the CPU 400 executes the reception start process (step S201). In the reception start process, the CPU 400 clears a sync mute flag and an unstable flag, which are provided in the storage area of the RAM included in the storage unit 401 and will be described later, and sets them to the initial state, ie, the OFF state. After executing the process of step S201, the reception control unit 40 causes the HDMI reception unit 403 to start receiving data signals and clock signals (step S202). Thereafter, the HDMI receiving section 403 sequentially receives data signals and clock signals from the projection control apparatus 3 under the control of the reception control section 40 . After executing the process of step S202, the CPU 400 executes a mute execution control process for controlling execution of the mute process (step S203). Details of the mute execution control process executed in step S203 will be described later.

After executing the mute execution control process in step S203, the CPU 400 determines whether or not the sync mute flag is on (step S204). The sync mute flag is set to the on state when the mute processing unit 42 is executing the mute processing, and is set to the off state when the mute processing unit 42 is not executing the mute processing. In step S204, CPU 400 determines whether or not mute processing unit 42 is executing mute processing by determining whether or not the sync mute flag is ON.

If it is determined in step S204 that the sync mute flag is off, that is, if it is determined that the mute processing unit 42 is not executing mute processing (step S204; No), the output unit 41 outputs the HDMI The receiving unit 403 outputs an image and sound according to the data signal received from the projection control device 3 (step S205). In step S205, the output unit 41 controls the image projection unit 406 to project the content image represented by the content image signal included in the received data signal onto the projection surface 2, and controls the audio output unit 407 to display the data. The content audio represented by the content audio signal included in the signal is output. After executing the process of step S205, the process proceeds to step S206. If it is determined in step S204 that the sync mute flag is ON, that is, if it is determined that the mute processing unit 42 is executing mute processing (step S204; Yes), the image is displayed according to the data signal. And the process moves to step S206 without executing the process of step S205 for outputting the voice.

At step S206, the CPU 400 determines whether or not the HDMI receiving unit 403 has received an output end signal from the projection control apparatus 3 (step S206). If it is determined in step S206 that the HDMI receiving unit 403 has not received the output end signal (step S206; No), the process returns to step S203. When it is determined in step S206 that the HDMI receiving unit 403 has received the output end signal (step S206; Yes), the reception control unit 40 causes the HDMI receiving unit 403 to end reception of the data signal and the clock signal ( Step S207), the reception process is terminated.

Details of the mute execution control process executed in step S203 of the reception process described above will be described below. In step S203, the CPU 400 executes mute execution control processing shown in the flowchart of FIG.

When the mute execution control process shown in the flowchart of FIG. 8 is started, first, the CPU 400 determines whether or not the sync mute flag is ON (step S301). If it is determined in step S301 that the sync mute flag is ON (step S301; Yes), the process proceeds to step S305. If it is determined in step S301 that the sync mute flag is off (step S301; No), the CPU 400 determines whether or not the HDMI receiving section 403 has received a mute instruction signal from the projection control apparatus 3 ( step S302). When it is determined in step S302 that the HDMI receiving unit 403 has not received the mute instruction signal (step S302; No), the CPU 400 ends the mute execution control process. When it is determined in step S302 that the HDMI receiving unit 403 has received the mute instruction signal (step S302; Yes), the mute processing unit 42 starts mute processing (step S303). After executing the process of step S303, the CPU 400 sets the sync mute flag to the ON state (step S304). After executing the process of step S304, the process proceeds to step S305. Thus, the sync mute flag is set to the on state (step S304) in response to the mute processing unit 42 starting the mute processing (step S303).

At step S305, CPU 400 determines whether or not the unstable flag is on (step S305). The unstable flag is set to the OFF state when the reception state has not changed from the stable signal state to the unstable signal state after the timing at which the HDMI receiving section 403 receives the mute instruction signal. is set to the ON state when the receiving state has changed from a stable signal state to an unstable signal state after receiving the mute instruction signal. In step S305, the CPU 400 determines whether or not the unstable flag is ON, thereby changing the reception state from the stable signal state to the unstable signal state after the timing at which the HDMI receiving unit 403 receives the mute instruction signal. It is determined whether or not it has become In the processing of step S305, when the sync mute flag is ON (step S301; Yes) or when the HDMI receiving unit 403 receives a mute instruction signal (step S302; Yes), mute processing is started ( Step S303) is executed after the sync mute flag is turned on (step S304). That is, the process of step S305 is performed in a state in which the mute process is being performed after the timing at which the HDMI receiving unit 403 receives the mute instruction signal.

If it is determined in step S305 that the unstable flag is off, that is, after the timing at which the HDMI receiving unit 403 receives the mute instruction signal, the reception state has not changed from the stable signal state to the unstable signal state. If it is determined that the frequency of the clock signal received by the HDMI receiver 403 from the projection control apparatus 3 is constant (step S305; No), the reception state determination unit 43 instructs the clock signal stability determination circuit 404 whether the frequency of the clock signal received by the HDMI receiver 403 from the projection control apparatus 3 is constant. is determined (step S306). If it is determined in step S306 that the frequency of the clock signal is disturbed (step S306; No), the reception state determination unit 43 determines that the reception state has changed from a stable signal state to an unstable signal state (step S307). ). With such a configuration, the reception state determination unit 43 determines that the reception state has not changed from the stable signal state to the unstable signal state after the timing at which the HDMI reception unit 403 receives the mute instruction signal. When the clock signal is continuously received at a constant frequency (step S305; No), when the frequency of the clock signal is disturbed (step S306; No), it is determined that the reception state has changed from a stable signal state to an unstable signal state. It is determined (step S307). After executing the process of step S307, the CPU 400 sets the unstable flag to the ON state (step S308). As described above, the unstable flag is set to the ON state when the reception state changes from the stable signal state to the unstable signal state after the timing when the HDMI receiving unit 403 receives the mute instruction signal (step S307). (step S308). After executing the process of step S308, the process moves to step S310. When it is determined in step S306 that the frequency of the clock signal is constant (step S306; Yes), the reception state determination unit 43 determines that the current reception state is a stable signal state (step S309). After executing the process of step S309, the process moves to step S310.

In step S305, if it is determined that the unstable flag is ON, that is, after the timing at which the HDMI receiving unit 403 receives the mute instruction signal, the reception state changes from the stable signal state to the unstable signal state. (step S305; Yes), the reception state determination unit 43 instructs the clock signal stability determination circuit 404 whether the frequency of the clock signal received by the HDMI reception unit 403 from the projection control apparatus 3 is constant. It is determined whether or not (step S313). If it is determined in step S313 that the frequency of the clock signal is disturbed (step S313; No), the reception state determination unit 43 determines that the current reception state is an unstable signal state (step S314). After executing the process of step S314, the process proceeds to step S310.

At step S310, the CPU 400 determines whether or not the HDMI receiving section 403 has received a mute release signal from the projection control apparatus 3 (step S310). When it is determined in step S310 that the HDMI receiving unit 403 has not received the mute release signal (step S310; No), the CPU 400 terminates the mute execution control process. If it is determined in step S310 that the HDMI receiving unit 403 has received the mute release signal (step S310; Yes), the mute processing unit 42 ends the mute processing (step S311). After executing the process of step S311, the CPU 400 clears the sync mute flag to set it to the OFF state (step S312), and terminates the mute execution control process. With such a configuration, when the HDMI receiving unit 403 receives the mute cancellation signal (step S310; Yes), the projection device 4 ends the mute processing (step S311). Also, in this way, the sync mute flag is set to the off state (step S312) in response to the mute processing unit 42 ending the mute processing (step S311).

When it is determined in step S313 that the frequency of the clock signal is constant (step S313; Yes), the reception state determination unit 43 determines that the reception state has changed from the unstable signal state to the stable signal state (step S315). ). With such a configuration, the reception state determination unit 43 detects that the HDMI reception unit 403 continues to receive the clock signal at a constant frequency after the reception state changes from the stable signal state to the unstable signal state (step S305; Yes). If it becomes possible (step S313; Yes), it is determined that the reception state has changed from the unstable signal state to the stable signal state (step S315). After executing the process of step S315, the CPU 400 clears the unstable flag and sets it to the OFF state (step S316). After executing the process of step S316, the mute processing unit 42 ends the mute process (step S311). After executing the process of step S311, the CPU 400 clears the sync mute flag to set it to the OFF state (step S312), and terminates the mute execution control process. Thus, the unstable flag is set to the off state (step S316) in response to the mute processing unit 42 ending the mute processing (step S311).

As described above, after the timing when the HDMI receiving unit 403 receives the mute instruction signal (step S302; Yes), the frequency of the clock signal that the HDMI receiving unit 403 continues to receive at a constant frequency is disturbed (step Based on S306; No), when the reception state determination unit 43 determines that the reception state has changed from the stable signal state to the unstable signal state (step S307), the unstable flag is set to the ON state (step S308). . When the unstable flag is ON while the muting process is being executed (step S305; Yes), the projection device 4 changes the receiving state from the unstable signal state to the stable signal state (step S315). Then, the mute processing ends without executing the processing of step S310 for determining whether or not the HDMI receiving unit 403 has received the mute release signal (step S311). With such a configuration, when the reception state changes from the stable signal state to the unstable signal state after the timing when the HDMI receiving unit 403 receives the mute instruction signal, the projection device 4 changes the reception state from the unstable signal state to the unstable signal state. Even if the HDMI receiving unit 403 does not receive the mute release signal when the signal becomes stable, the mute processing is terminated.

As described above, after the HDMI receiving unit 403 receives the mute instruction signal, the projection device 4 detects that the reception state of the clock signal by the HDMI receiving unit 403 has changed from the stable signal state to the unstable signal state. In addition, when it is detected that the reception state of the clock signal has changed from the unstable signal state to the stable signal state, the mute processing is terminated even if the HDMI receiving unit 403 has not received the mute release signal (that is, the output is stopped). command to cancel). According to such a configuration, muting processing, which is an example of output stop, can be appropriately controlled.

Further, when the HDMI receiving unit 403 receives the mute cancellation signal, the projection device 4 ends the mute processing. According to such a configuration, it is possible to appropriately control the mute processing.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above embodiments, and various modifications can be made without departing from the gist of the present invention.

For example, in the above embodiment, the mute processing unit 42 detects that the reception state of the clock signal by the HDMI reception unit 403 has changed from the signal stable state to the signal unstable state after the HDMI reception unit 403 receives the mute instruction signal. When the reception state determination unit 43 detects that the reception state has changed from the unstable signal state to the stable signal state, the reception state continues to be the stable signal state. The muting process may be continued (that is, the output is stopped) until the duration exceeds the reference time, and the muting process may be terminated when the duration exceeds the reference time. Specifically, in this case, a timer for measuring the duration is provided in the RAM storage area of the storage unit 401, and the mute processing unit 42 mutes when the timer value of the timer is equal to or less than a threshold value corresponding to the reference time. The processing may be continued, and the mute processing may be terminated when the timer value exceeds the threshold value.

According to such a configuration, the reception state of the projection device 4 changes from the stable signal state to the unstable signal state after the timing when the HDMI receiving unit 403 receives the mute instruction signal, and then changes from the unstable signal state to the unstable signal state. When the signal becomes stable, if the reception becomes unstable again within the reference time after the signal becomes stable, the mute processing continues, so the reception becomes unstable. By outputting an image and sound according to a data signal received during a certain period, it is possible to reduce the possibility of occurrence of image flicker or sound noise. That is, according to such a configuration, it is possible to appropriately control the muting process.

In the above-described embodiment, the reception state determination unit 43 determines whether the reception state of the clock signal by the HDMI reception unit 403 is a stable signal state, an unstable signal state, and whether the frequency of the clock signal received by the HDMI reception unit 403 is constant. A reception abnormality state in which the HDMI receiving unit 403 cannot receive a data signal even though the data signal is not received is determined. may be configured to control Due to factors other than the change in the frequency of the clock signal transmitted from the projection control apparatus 3, such as poor quality of the HDMI cable 5, connection failure between the connector of the HDMI receiving unit 403 and the HDMI cable 5, the projection control apparatus 3 When the communication state between the projector and the projection device 4 deteriorates, the reception state becomes a reception abnormal state.

In this case, the reception state determination unit 43 determines whether or not the HDMI reception unit 403 can normally receive the data signal from the projection control apparatus 3. If it is determined that the HDMI reception unit 403 can normally receive the data signal, , the reception state is determined to be a stable signal state, and when it is determined that the HDMI receiving unit 403 cannot receive the data signal normally, the reception state is determined to be an unstable signal state or an abnormal reception state. More specifically, the reception state determination unit 43 detects the error rate of the data signal received by the HDMI reception unit 403, and if the detected error rate is equal to or less than a preset normal threshold, HDMI reception is determined. If the unit 403 determines that the data signal can be received normally and the detected error rate is greater than the normal threshold, the HDMI receiving unit 403 determines that the data signal cannot be received normally. In this modification, the first error rate is the data signal error rate when the HDMI receiving unit 403 can normally receive the data signal, and the data signal error rate when the HDMI receiving unit 403 cannot normally receive the signal. A second error rate is measured, and a value larger than the measured first error rate and smaller than the measured second error rate is set in advance as a normal threshold. When the reception state determination unit 43 determines that the reception state is the unstable signal state or the abnormal reception state, the clock signal stability determination circuit 404 determines whether the frequency of the clock signal received by the HDMI reception unit 403 is constant. If it is determined that the frequency of the clock signal is constant, it is determined that the reception state is abnormal, and if it is determined that the frequency of the clock signal is disturbed, the reception state is determined to be a signal failure Determine that it is in a stable state.

When the mute processing unit 42 determines that the reception state has changed from the stable signal state to the abnormal reception state after the timing when the HDMI reception unit 403 receives the mute instruction signal, the HDMI reception unit 403 controls the projection of the mute release signal. The muting process continues until the signal is received from the device 3, and ends when the HDMI receiving unit 403 receives the mute release signal. Further, when it is determined that the reception state has changed from the stable signal state to the abnormal reception state after the timing when the HDMI receiving unit 403 receives the mute instruction signal, the mute processing unit 42 changes the reception state from the abnormal reception state to the abnormal reception state. The muting process is continued when the stable state is reached, and the muting process ends when the HDMI receiving unit 403 receives the mute release signal. In other words, the reception state determination unit 43 of the mute processing unit 42 detects that the reception state of the clock signal has changed from the stable signal state to the abnormal reception state after the HDMI reception unit 403 receives the mute instruction signal. In addition, when the reception state determination unit 43 detects that the reception state of the clock signal has changed from the abnormal reception state to the stable signal state, the muting process is continued (that is, the output stop is continued).

With such a configuration, after the timing when the HDMI receiving unit 403 receives the mute instruction signal and the mute process is started, due to factors such as connection failure between the connector provided in the HDMI receiving unit 403 and the HDMI cable 5, When the reception state changes from a stable signal state to an abnormal reception state, and then when the reception state changes from the abnormal reception state to a stable signal state due to the removal of the cause, the projection control apparatus 3 transmits a mute release signal. It is possible to reduce the possibility that the mute process is terminated even though the That is, according to such a configuration, it is possible to appropriately control the muting process, which is an example of stopping the output.

In addition, it is possible to provide a dedicated receiving device having a configuration for realizing each function according to the present invention as a receiving device according to the present invention. It can also function as a receiver. That is, by applying a program for realizing each function of the receiving device according to the present invention so that a processor such as a CPU that controls the existing receiving device can execute the existing receiving device, It can function as a receiving device.

Note that the application method of such a program is arbitrary. The program can be applied by storing it in a computer-readable storage medium such as a flexible disk, CD (Compact Disc)-ROM, DVD (Digital Versatile Disc)-ROM, memory card, or the like. Furthermore, a program can be superimposed on a carrier wave and applied via a communication medium such as the Internet. For example, the program may be posted and distributed on a bulletin board (BBS: Bulletin Board System) on a communication network. Then, the above processing may be executed by starting this program and executing it in the same manner as other application programs under the control of an OS (Operating System).

Although the preferred embodiments of the present invention have been described above, the present invention is not limited to such specific embodiments, and the present invention includes the invention described in the claims and their equivalents. included. The invention described in the original claims of the present application is appended below.

(Appendix 1)
a signal receiver that receives a data signal, a clock signal, an output stop signal, and an output stop release signal transmitted from the transmitter;
at least one processor;
with
The at least one processor
directing an output in response to the received data signal;
If the output stop signal is received during output according to the data signal, instructing to stop output according to the data signal;
After receiving the output stop signal, it is detected that the reception state of the clock signal has changed from the first state to the second state, and the reception state of the clock signal has changed from the second state to the first state. when detecting that the output stop is canceled even if the output stop cancellation signal is not received;
A receiving device characterized by:

(Appendix 2)
when the receiving state of the clock signal is the first state, the signal receiving unit can receive the data signal;
When the receiving state of the clock signal is the second state, the signal receiving unit may not be able to receive the data signal.
The receiving device according to appendix 1, characterized by:

(Appendix 3)
When the at least one processor receives the output suspension release signal, it instructs to release the output suspension.
The receiver according to appendix 1 or 2, characterized by:

(Appendix 4)
The at least one processor detects that a reception state of the clock signal has changed from the first state to the second state after receiving the output stop signal, and detects that the reception state of the clock signal has changed to the second state. When it is detected that the second state has changed to the first state, the output stop is continued until the reception state of the clock signal continues and the duration time in the first state exceeds a reference time, and the duration time is exceeded. instructs to cancel the output suspension when exceeds the reference time;
The receiver according to any one of appendices 1 to 3, characterized by:

(Appendix 5)
After receiving the output stop signal, the at least one processor may not be able to receive the data signal even though the reception state of the clock signal is such that the frequency of the clock signal is constant from the first state. continuing to stop the output when detecting a change to a third state and detecting a change in the receiving state of the clock signal from the third state to the first state;
The receiver according to any one of appendices 1 to 4, characterized by:

(Appendix 6)
an image projection unit that projects an image onto a projection plane;
an audio output unit that outputs audio;
further comprising
The at least one processor
causing the image projection unit to project an image corresponding to the data signal;
causing the audio output unit to output audio corresponding to the data signal;
The receiver according to any one of appendices 1 to 5, characterized by:

(Appendix 7)
instructing an output according to a data signal received from a transmitting device;
If an output stop signal is received from the transmitting device during output according to the data signal, instructing to stop output according to the data signal;
After receiving the output stop signal, detecting that the reception state of the clock signal received from the transmission device has changed from the first state to the second state, and changing the reception state of the clock signal from the second state to the above When detecting a change to the first state, instructing to cancel the output suspension even if an output suspension cancellation signal has not been received from the transmitting device;
A receiving method characterized by:

(Appendix 8)
at least one processor,
directing an output according to a data signal received from a transmitting device;
If an output stop signal is received from the transmitting device during output according to the data signal, instructing to stop output according to the data signal;
After receiving the output stop signal, detecting that the reception state of the clock signal received from the transmission device has changed from the first state to the second state, and changing the reception state of the clock signal from the second state to the above When detecting that the state has changed to the first state, giving an instruction to cancel the output suspension even if an output suspension cancellation signal has not been received from the transmitting device;
A program characterized by

1 Projection system 2 Projection surface 3 Projection control device 4 Projection device 5 HDMI cable 30 Instruction reception unit 31 Signal generation Unit 32 Transmission control unit 40 Reception control unit 41 Output unit 42 Mute processing unit 43 Reception state determination unit 300, 400 CPU 301, 401 ... storage section 302, 402 ... operation section 303 ... display section 304 ... clock signal generation circuit 305 ... HDMI transmission section 306, 405 ... wireless communication Units 307, 408 System bus 403 HDMI receiver 404 Clock signal stability determination circuit 406 Image projection unit 407 Audio output unit T1 to T8 ·Times of Day

Claims (7)

a signal receiver that receives a data signal, a clock signal, an output stop signal, and an output stop release signal transmitted from the transmitter;
at least one processor;
with
The at least one processor
directing an output in response to the received data signal;
If the output stop signal is received during output according to the data signal, instructing to stop output according to the data signal;
After receiving the output stop signal, the clock signal is changed from a first state in which the clock signal is stable and the data signal can be received to a second state in which the frequency of the clock signal is more unstable than in the first state. and instructing to cancel the output stop even if the output stop cancel signal is not received when detecting that the state has changed from the second state to the first state, and
After receiving the output stop signal, detecting a change to a third state in which the data signal cannot be received although the frequency of the clock signal is constant , and changing from the third state to the first state. If it is detected that the output has been stopped, continue the output stop;
A receiving device characterized by: The at least one processor detects an error rate of the received data signal, and determines that the data signal can be normally received when the detected error rate is equal to or less than a preset normal threshold. determining that the data signal cannot be received normally if the detected error rate is greater than a normal threshold;
2. The receiving apparatus according to claim 1, characterized by: When the at least one processor receives the output suspension release signal, it instructs to release the output suspension.
3. The receiver according to claim 1 or 2, characterized by: The at least one processor detects that a reception state of the clock signal has changed from the first state to the second state after receiving the output stop signal, and detects that the reception state of the clock signal has changed to the second state. When it is detected that the second state has changed to the first state, the output stop is continued until the reception state of the clock signal continues and the duration time in the first state exceeds a reference time, and the duration time is exceeded. instructs to cancel the output suspension when exceeds the reference time;
4. The receiving apparatus according to any one of claims 1 to 3, characterized by: an image projection unit that projects an image onto a projection plane;
an audio output unit that outputs audio;
further comprising
The at least one processor
causing the image projection unit to project an image corresponding to the data signal;
causing the audio output unit to output audio corresponding to the data signal;
5. The receiver according to any one of claims 1 to 4, characterized in that: instructing an output according to a data signal received from a transmitting device;
If an output stop signal is received from the transmitting device during output according to the data signal, instructing to stop output according to the data signal;
After receiving the output stop signal, the clock signal from the transmitting device is in a stable state and the data signal can be received from a first state to a second state in which the frequency of the clock signal is more unstable than in the first state. When the change is detected and the change from the second state to the first state is detected, even if the output stop release signal is not received from the transmitting device, the release of the output stop is instructed. ,
After receiving the output stop signal, detecting a change to a third state in which the data signal cannot be received even though the frequency of the clock signal from the transmitting device is constant , and from the third state to the When detecting that the state has changed to the first state, continuing the output stop;
A receiving method characterized by: at least one processor,
directing an output according to a data signal received from a transmitting device;
If an output stop signal is received from the transmitting device during output according to the data signal, instructing to stop output according to the data signal;
After receiving the output stop signal, the clock signal from the transmitting device is in a stable state and the data signal can be received from a first state to a second state in which the frequency of the clock signal is more unstable than in the first state. When the change is detected and the change from the second state to the first state is detected, the release of the output stop is instructed even if the output stop release signal is not received from the transmitting device. ,
After receiving the output stop signal, detecting a change to a third state in which the data signal cannot be received even though the frequency of the clock signal from the transmitting device is constant , and from the third state to the When detecting that the state has changed to the first state, continuing the output stop;
A program characterized by

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